/* * Copyright (C) 2014 Pavel Kirienko */ #include #include #include #include "../clock.hpp" /* * Beware! * The code you're about to look at desperately needs some cleaning. */ struct RxFrameGenerator { static const uavcan::TransferBufferManagerKey DEFAULT_KEY; enum { TARGET_NODE_ID = 126 }; uint16_t data_type_id; uavcan::TransferBufferManagerKey bufmgr_key; RxFrameGenerator(uint16_t data_type_id, const uavcan::TransferBufferManagerKey& bufmgr_key = DEFAULT_KEY) : data_type_id(data_type_id) , bufmgr_key(bufmgr_key) { } uavcan::RxFrame operator()(uint8_t iface_index, const std::string& data, uint8_t frame_index, bool last, uint8_t transfer_id, uint64_t ts_monotonic, uint64_t ts_utc = 0) { const uavcan::NodeID dst_nid = (bufmgr_key.getTransferType() == uavcan::TransferTypeMessageBroadcast) ? uavcan::NodeID::Broadcast : TARGET_NODE_ID; uavcan::Frame frame(data_type_id, bufmgr_key.getTransferType(), bufmgr_key.getNodeID(), dst_nid, frame_index, transfer_id, last); EXPECT_EQ(data.length(), frame.setPayload(reinterpret_cast(data.c_str()), unsigned(data.length()))); return uavcan::RxFrame(frame, uavcan::MonotonicTime::fromUSec(ts_monotonic), uavcan::UtcTime::fromUSec(ts_utc), iface_index); } }; const uavcan::TransferBufferManagerKey RxFrameGenerator::DEFAULT_KEY(42, uavcan::TransferTypeMessageBroadcast); template struct Context { uavcan::PoolManager<1> poolmgr; // We don't need dynamic memory for this test uavcan::TransferReceiver receiver; // Must be default constructible and copyable uavcan::TransferBufferManager bufmgr; Context() : bufmgr(poolmgr) { assert(poolmgr.allocate(1) == NULL); } ~Context() { // We need to destroy the receiver before its buffer manager receiver = uavcan::TransferReceiver(); } }; static bool matchBufferContent(const uavcan::ITransferBuffer* tbb, const std::string& content) { uint8_t data[1024]; std::fill(data, data + sizeof(data), 0); if (content.length() > sizeof(data)) { std::cerr << "matchBufferContent(): Content is too long" << std::endl; std::exit(1); } tbb->read(0, data, unsigned(content.length())); if (std::equal(content.begin(), content.end(), data)) { return true; } std::cout << "Buffer content mismatch:" << "\n\tExpected: " << content << "\n\tActually: " << reinterpret_cast(data) << std::endl; return false; } #define CHECK_NOT_COMPLETE(x) ASSERT_EQ(uavcan::TransferReceiver::ResultNotComplete, (x)) #define CHECK_COMPLETE(x) ASSERT_EQ(uavcan::TransferReceiver::ResultComplete, (x)) #define CHECK_SINGLE_FRAME(x) ASSERT_EQ(uavcan::TransferReceiver::ResultSingleFrame, (x)) TEST(TransferReceiver, Basic) { using uavcan::TransferReceiver; Context<32> context; RxFrameGenerator gen(789); uavcan::TransferReceiver& rcv = context.receiver; uavcan::ITransferBufferManager& bufmgr = context.bufmgr; uavcan::TransferBufferAccessor bk(context.bufmgr, RxFrameGenerator::DEFAULT_KEY); /* * Empty */ ASSERT_EQ(TransferReceiver::getDefaultTransferInterval(), rcv.getInterval()); ASSERT_EQ(0, rcv.getLastTransferTimestampMonotonic().toUSec()); /* * Single frame transfer with zero ts, must be ignored */ CHECK_NOT_COMPLETE(rcv.addFrame(gen(0, "Foo", 0, true, 0, 0), bk)); ASSERT_EQ(TransferReceiver::getDefaultTransferInterval(), rcv.getInterval()); ASSERT_EQ(0, rcv.getLastTransferTimestampMonotonic().toUSec()); /* * Valid compound transfer * Args: iface_index, data, frame_index, last, transfer_id, timestamp */ CHECK_NOT_COMPLETE(rcv.addFrame(gen(0, "\x34\x12" "345678", 0, false, 0, 100), bk)); CHECK_COMPLETE(rcv.addFrame(gen(0, "foo", 1, true, 0, 200), bk)); ASSERT_TRUE(matchBufferContent(bufmgr.access(gen.bufmgr_key), "345678foo")); ASSERT_EQ(0x1234, rcv.getLastTransferCrc()); ASSERT_EQ(TransferReceiver::getDefaultTransferInterval(), rcv.getInterval()); // Not initialized yet ASSERT_EQ(100, rcv.getLastTransferTimestampMonotonic().toUSec()); /* * Compound transfer mixed with invalid frames; buffer was not released explicitly */ CHECK_NOT_COMPLETE(rcv.addFrame(gen(0, "qwe", 0, false, 0, 300), bk)); // Previous TID, rejected CHECK_NOT_COMPLETE(rcv.addFrame(gen(1, "rty", 0, false, 0, 300), bk)); // Previous TID, wrong iface CHECK_NOT_COMPLETE(rcv.addFrame(gen(0, "\x9a\x78" "345678", 0, false, 1, 1000), bk)); CHECK_NOT_COMPLETE(rcv.addFrame(gen(0, "qwertyui", 0, false, 1, 1100), bk)); // Old FI CHECK_NOT_COMPLETE(rcv.addFrame(gen(0, "abcdefgh", 1, false, 1, 1200), bk)); CHECK_NOT_COMPLETE(rcv.addFrame(gen(0, "45678910", 1, false, 2, 1300), bk)); // Next TID, but FI > 0 CHECK_NOT_COMPLETE(rcv.addFrame(gen(1, "", 2, true, 1, 1300), bk)); // Wrong iface CHECK_NOT_COMPLETE(rcv.addFrame(gen(0, "", 31, true, 1, 1300), bk)); // Unexpected FI CHECK_COMPLETE( rcv.addFrame(gen(0, "", 2, true, 1, 1300), bk)); ASSERT_TRUE(matchBufferContent(bufmgr.access(gen.bufmgr_key), "345678abcdefgh")); ASSERT_EQ(0x789A, rcv.getLastTransferCrc()); ASSERT_GT(TransferReceiver::getDefaultTransferInterval(), rcv.getInterval()); ASSERT_LT(TransferReceiver::getMinTransferInterval(), rcv.getInterval()); ASSERT_EQ(1000, rcv.getLastTransferTimestampMonotonic().toUSec()); ASSERT_FALSE(rcv.isTimedOut(tsMono(1000))); ASSERT_FALSE(rcv.isTimedOut(tsMono(5000))); ASSERT_TRUE(rcv.isTimedOut(tsMono(60000000))); /* * Single-frame transfers */ CHECK_NOT_COMPLETE(rcv.addFrame(gen(0, "qwe", 0, true, 1, 2000), bk)); // Previous TID CHECK_NOT_COMPLETE(rcv.addFrame(gen(1, "qwe", 0, true, 2, 2100), bk)); // Wrong iface CHECK_SINGLE_FRAME(rcv.addFrame(gen(0, "qwe", 0, true, 2, 2200), bk)); ASSERT_FALSE(bufmgr.access(gen.bufmgr_key)); // Buffer must be removed ASSERT_GT(TransferReceiver::getDefaultTransferInterval(), rcv.getInterval()); ASSERT_EQ(2200, rcv.getLastTransferTimestampMonotonic().toUSec()); CHECK_SINGLE_FRAME(rcv.addFrame(gen(0, "", 0, true, 3, 2500), bk)); ASSERT_EQ(2500, rcv.getLastTransferTimestampMonotonic().toUSec()); CHECK_NOT_COMPLETE(rcv.addFrame(gen(0, "", 0, true, 0, 3000), bk)); // Old TID CHECK_NOT_COMPLETE(rcv.addFrame(gen(0, "", 0, true, 1, 3100), bk)); // Old TID CHECK_NOT_COMPLETE(rcv.addFrame(gen(0, "", 0, true, 3, 3200), bk)); // Old TID CHECK_NOT_COMPLETE(rcv.addFrame(gen(1, "", 0, true, 0, 3300), bk)); // Old TID, wrong iface CHECK_NOT_COMPLETE(rcv.addFrame(gen(1, "", 0, true, 2, 3400), bk)); // Old TID, wrong iface CHECK_NOT_COMPLETE(rcv.addFrame(gen(1, "", 0, true, 3, 3500), bk)); // Old TID, wrong iface CHECK_SINGLE_FRAME(rcv.addFrame(gen(0, "", 0, true, 4, 3600), bk)); ASSERT_EQ(3600, rcv.getLastTransferTimestampMonotonic().toUSec()); /* * Timeouts */ CHECK_NOT_COMPLETE(rcv.addFrame(gen(1, "qwe", 0, true, 1, 100000), bk)); // Wrong iface - ignored CHECK_SINGLE_FRAME(rcv.addFrame(gen(1, "qwe", 0, true, 6, 1500000), bk)); // Accepted due to iface timeout ASSERT_EQ(1500000, rcv.getLastTransferTimestampMonotonic().toUSec()); CHECK_NOT_COMPLETE(rcv.addFrame(gen(0, "qwe", 0, true, 7, 1500100), bk)); // Ignored - old iface 0 CHECK_SINGLE_FRAME(rcv.addFrame(gen(1, "qwe", 0, true, 7, 1500100), bk)); ASSERT_EQ(1500100, rcv.getLastTransferTimestampMonotonic().toUSec()); CHECK_NOT_COMPLETE(rcv.addFrame(gen(1, "qwe", 0, true, 7, 1500100), bk)); // Old TID CHECK_SINGLE_FRAME(rcv.addFrame(gen(0, "qwe", 0, true, 7, 100000000), bk)); // Accepted - global timeout ASSERT_EQ(100000000, rcv.getLastTransferTimestampMonotonic().toUSec()); CHECK_SINGLE_FRAME(rcv.addFrame(gen(0, "qwe", 0, true, 0, 100000100), bk)); ASSERT_EQ(100000100, rcv.getLastTransferTimestampMonotonic().toUSec()); ASSERT_TRUE(rcv.isTimedOut(tsMono(900000000))); CHECK_NOT_COMPLETE(rcv.addFrame(gen(1, "\x78\x56" "345678", 0, false, 0, 900000000), bk)); // Global timeout CHECK_NOT_COMPLETE(rcv.addFrame(gen(0, "12345678", 0, false, 0, 900000100), bk)); // Wrong iface CHECK_NOT_COMPLETE(rcv.addFrame(gen(0, "qwe", 1, true, 0, 900000200), bk)); // Wrong iface CHECK_COMPLETE( rcv.addFrame(gen(1, "qwe", 1, true, 0, 900000200), bk)); ASSERT_EQ(900000000, rcv.getLastTransferTimestampMonotonic().toUSec()); ASSERT_FALSE(rcv.isTimedOut(tsMono(1000))); ASSERT_FALSE(rcv.isTimedOut(tsMono(900000200))); ASSERT_TRUE(rcv.isTimedOut(tsMono(1000 * 1000000))); ASSERT_LT(TransferReceiver::getDefaultTransferInterval(), rcv.getInterval()); ASSERT_LE(TransferReceiver::getMinTransferInterval(), rcv.getInterval()); ASSERT_GE(TransferReceiver::getMaxTransferInterval(), rcv.getInterval()); ASSERT_TRUE(matchBufferContent(bufmgr.access(gen.bufmgr_key), "345678qwe")); ASSERT_EQ(0x5678, rcv.getLastTransferCrc()); /* * Destruction */ ASSERT_TRUE(bufmgr.access(gen.bufmgr_key)); context.receiver.~TransferReceiver(); // TransferReceiver does not own the buffer, it must not be released! ASSERT_TRUE(bufmgr.access(gen.bufmgr_key)); // Making sure that the buffer is still there } TEST(TransferReceiver, OutOfBufferSpace_32bytes) { Context<32> context; RxFrameGenerator gen(789); uavcan::TransferReceiver& rcv = context.receiver; uavcan::ITransferBufferManager& bufmgr = context.bufmgr; uavcan::TransferBufferAccessor bk(context.bufmgr, RxFrameGenerator::DEFAULT_KEY); /* * Simple transfer, maximum buffer length */ CHECK_NOT_COMPLETE(rcv.addFrame(gen(1, "12345678", 0, false, 1, 100000000), bk)); // 6 CHECK_NOT_COMPLETE(rcv.addFrame(gen(1, "12345678", 1, false, 1, 100000100), bk)); // 14 CHECK_NOT_COMPLETE(rcv.addFrame(gen(1, "12345678", 2, false, 1, 100000200), bk)); // 22 CHECK_NOT_COMPLETE(rcv.addFrame(gen(1, "12345678", 3, false, 1, 100000300), bk)); // 30 CHECK_COMPLETE( rcv.addFrame(gen(1, "12", 4, true, 1, 100000400), bk)); // 32 ASSERT_EQ(100000000, rcv.getLastTransferTimestampMonotonic().toUSec()); ASSERT_TRUE(matchBufferContent(bufmgr.access(gen.bufmgr_key), "34567812345678123456781234567812")); ASSERT_EQ(0x3231, rcv.getLastTransferCrc()); // CRC from "12", which is 0x3231 in little endian /* * Transfer longer than available buffer space */ CHECK_NOT_COMPLETE(rcv.addFrame(gen(1, "12345678", 0, false, 2, 100001000), bk)); // 6 CHECK_NOT_COMPLETE(rcv.addFrame(gen(1, "12345678", 1, false, 2, 100001100), bk)); // 14 CHECK_NOT_COMPLETE(rcv.addFrame(gen(1, "12345678", 2, false, 2, 100001200), bk)); // 22 CHECK_NOT_COMPLETE(rcv.addFrame(gen(1, "12345678", 3, false, 2, 100001200), bk)); // 30 CHECK_NOT_COMPLETE(rcv.addFrame(gen(1, "12345678", 4, true, 2, 100001300), bk)); // 38 // EOT, ignored - lost sync ASSERT_EQ(100000000, rcv.getLastTransferTimestampMonotonic().toUSec()); // Timestamp will not be overriden ASSERT_FALSE(bufmgr.access(gen.bufmgr_key)); // Buffer should be removed ASSERT_EQ(1, rcv.yieldErrorCount()); ASSERT_EQ(0, rcv.yieldErrorCount()); } TEST(TransferReceiver, UnterminatedTransfer) { Context<512> context; RxFrameGenerator gen(789); uavcan::TransferReceiver& rcv = context.receiver; uavcan::ITransferBufferManager& bufmgr = context.bufmgr; uavcan::TransferBufferAccessor bk(context.bufmgr, RxFrameGenerator::DEFAULT_KEY); std::string content; for (uint8_t i = 0; i <= uavcan::Frame::MaxIndex; i++) { CHECK_NOT_COMPLETE(rcv.addFrame(gen(1, "12345678", i, false, 0, 1000U + i), bk)); // Last one will be dropped content += "12345678"; } CHECK_COMPLETE(rcv.addFrame(gen(1, "12345678", uavcan::Frame::MaxIndex, true, 0, 1100), bk)); ASSERT_EQ(1000, rcv.getLastTransferTimestampMonotonic().toUSec()); ASSERT_TRUE(matchBufferContent(bufmgr.access(gen.bufmgr_key), std::string(content, 2))); ASSERT_EQ(0x3231, rcv.getLastTransferCrc()); ASSERT_EQ(1, rcv.yieldErrorCount()); ASSERT_EQ(0, rcv.yieldErrorCount()); } TEST(TransferReceiver, OutOfOrderFrames) { Context<32> context; RxFrameGenerator gen(789); uavcan::TransferReceiver& rcv = context.receiver; uavcan::ITransferBufferManager& bufmgr = context.bufmgr; uavcan::TransferBufferAccessor bk(context.bufmgr, RxFrameGenerator::DEFAULT_KEY); CHECK_NOT_COMPLETE(rcv.addFrame(gen(1, "12345678", 0, false, 7, 100000000), bk)); CHECK_NOT_COMPLETE(rcv.addFrame(gen(1, "--------", 3, false, 7, 100000100), bk)); // Out of order CHECK_NOT_COMPLETE(rcv.addFrame(gen(1, "--------", 2, true, 7, 100000200), bk)); // Out of order CHECK_NOT_COMPLETE(rcv.addFrame(gen(1, "qwertyui", 1, false, 7, 100000300), bk)); CHECK_NOT_COMPLETE(rcv.addFrame(gen(1, "--------", 4, true, 7, 100000200), bk)); // Out of order CHECK_COMPLETE( rcv.addFrame(gen(1, "abcd", 2, true, 7, 100000400), bk)); ASSERT_EQ(100000000, rcv.getLastTransferTimestampMonotonic().toUSec()); ASSERT_TRUE(matchBufferContent(bufmgr.access(gen.bufmgr_key), "345678qwertyuiabcd")); ASSERT_EQ(0x3231, rcv.getLastTransferCrc()); ASSERT_EQ(3, rcv.yieldErrorCount()); ASSERT_EQ(0, rcv.yieldErrorCount()); } TEST(TransferReceiver, IntervalMeasurement) { Context<32> context; RxFrameGenerator gen(789); uavcan::TransferReceiver& rcv = context.receiver; uavcan::ITransferBufferManager& bufmgr = context.bufmgr; uavcan::TransferBufferAccessor bk(context.bufmgr, RxFrameGenerator::DEFAULT_KEY); static const int INTERVAL = 1000; uavcan::TransferID tid; uint64_t timestamp = 100000000; for (int i = 0; i < 1000; i++) { CHECK_NOT_COMPLETE(rcv.addFrame(gen(1, "12345678", 0, false, tid.get(), timestamp), bk)); CHECK_NOT_COMPLETE(rcv.addFrame(gen(1, "qwertyui", 1, false, tid.get(), timestamp), bk)); CHECK_COMPLETE( rcv.addFrame(gen(1, "abcd", 2, true, tid.get(), timestamp), bk)); ASSERT_TRUE(matchBufferContent(bufmgr.access(gen.bufmgr_key), "345678qwertyuiabcd")); ASSERT_EQ(0x3231, rcv.getLastTransferCrc()); ASSERT_EQ(timestamp, rcv.getLastTransferTimestampMonotonic().toUSec()); timestamp += uint64_t(INTERVAL); tid.increment(); } ASSERT_EQ(INTERVAL, rcv.getInterval().toUSec()); } TEST(TransferReceiver, Restart) { Context<32> context; RxFrameGenerator gen(789); uavcan::TransferReceiver& rcv = context.receiver; uavcan::ITransferBufferManager& bufmgr = context.bufmgr; uavcan::TransferBufferAccessor bk(context.bufmgr, RxFrameGenerator::DEFAULT_KEY); /* * This transfer looks complete, but must be ignored because of large delay after the first frame */ CHECK_NOT_COMPLETE(rcv.addFrame(gen(0, "--------", 0, false, 0, 100), bk)); // Begin CHECK_NOT_COMPLETE(rcv.addFrame(gen(0, "--------", 1, false, 0, 10000100), bk)); // Continue 10 sec later, expired CHECK_NOT_COMPLETE(rcv.addFrame(gen(0, "--------", 2, true, 0, 10000200), bk)); // Ignored /* * Begins immediately after, gets an iface timeout but completes OK */ CHECK_NOT_COMPLETE(rcv.addFrame(gen(1, "12345678", 0, false, 0, 10000300), bk)); // Begin CHECK_NOT_COMPLETE(rcv.addFrame(gen(1, "12345678", 1, false, 0, 12000300), bk)); // 2 sec later, iface timeout CHECK_COMPLETE( rcv.addFrame(gen(1, "12345678", 2, true, 0, 12000400), bk)); // OK nevertheless ASSERT_TRUE(matchBufferContent(bufmgr.access(gen.bufmgr_key), "3456781234567812345678")); ASSERT_EQ(0x3231, rcv.getLastTransferCrc()); /* * Begins OK, gets an iface timeout, switches to another iface */ CHECK_NOT_COMPLETE(rcv.addFrame(gen(1, "--------", 0, false, 1, 13000500), bk)); // Begin CHECK_NOT_COMPLETE(rcv.addFrame(gen(1, "--------", 1, false, 1, 16000500), bk)); // 3 sec later, iface timeout CHECK_NOT_COMPLETE(rcv.addFrame(gen(0, "--------", 1, false, 1, 16000600), bk)); // Same TID, another iface - ignore CHECK_NOT_COMPLETE(rcv.addFrame(gen(0, "--------", 1, false, 2, 16000700), bk)); // Not first frame - ignore CHECK_NOT_COMPLETE(rcv.addFrame(gen(0, "12345678", 0, false, 2, 16000800), bk)); // First, another iface - restart CHECK_NOT_COMPLETE(rcv.addFrame(gen(1, "--------", 2, true, 1, 16000600), bk)); // Old iface - ignore CHECK_NOT_COMPLETE(rcv.addFrame(gen(0, "12345678", 1, false, 2, 16000900), bk)); // Continuing CHECK_COMPLETE( rcv.addFrame(gen(0, "12345678", 2, true, 2, 16000910), bk)); // Done ASSERT_TRUE(matchBufferContent(bufmgr.access(gen.bufmgr_key), "3456781234567812345678")); ASSERT_EQ(0x3231, rcv.getLastTransferCrc()); ASSERT_EQ(1, rcv.yieldErrorCount()); ASSERT_EQ(0, rcv.yieldErrorCount()); } TEST(TransferReceiver, UtcTransferTimestamping) { Context<32> context; RxFrameGenerator gen(789); uavcan::TransferReceiver& rcv = context.receiver; uavcan::ITransferBufferManager& bufmgr = context.bufmgr; uavcan::TransferBufferAccessor bk(context.bufmgr, RxFrameGenerator::DEFAULT_KEY); /* * Zero UTC timestamp must be preserved */ CHECK_NOT_COMPLETE(rcv.addFrame(gen(1, "12345678", 0, false, 0, 1, 0), bk)); CHECK_NOT_COMPLETE(rcv.addFrame(gen(1, "qwertyui", 1, false, 0, 2, 0), bk)); CHECK_COMPLETE( rcv.addFrame(gen(1, "abcd", 2, true, 0, 3, 0), bk)); ASSERT_TRUE(matchBufferContent(bufmgr.access(gen.bufmgr_key), "345678qwertyuiabcd")); ASSERT_EQ(1, rcv.getLastTransferTimestampMonotonic().toUSec()); ASSERT_EQ(0, rcv.getLastTransferTimestampUtc().toUSec()); /* * Non-zero UTC timestamp */ CHECK_NOT_COMPLETE(rcv.addFrame(gen(1, "12345678", 0, false, 1, 4, 123), bk)); // This UTC is going to be preserved CHECK_NOT_COMPLETE(rcv.addFrame(gen(1, "qwertyui", 1, false, 1, 5, 0), bk)); // Following are ignored CHECK_COMPLETE( rcv.addFrame(gen(1, "abcd", 2, true, 1, 6, 42), bk)); ASSERT_TRUE(matchBufferContent(bufmgr.access(gen.bufmgr_key), "345678qwertyuiabcd")); ASSERT_EQ(4, rcv.getLastTransferTimestampMonotonic().toUSec()); ASSERT_EQ(123, rcv.getLastTransferTimestampUtc().toUSec()); /* * Single-frame transfers */ CHECK_SINGLE_FRAME(rcv.addFrame(gen(1, "abc", 0, true, 2, 10, 100000000), bk)); // Exact value is irrelevant ASSERT_EQ(10, rcv.getLastTransferTimestampMonotonic().toUSec()); ASSERT_EQ(100000000, rcv.getLastTransferTimestampUtc().toUSec()); /* * Restart recovery */ CHECK_NOT_COMPLETE(rcv.addFrame(gen(0, "12345678", 0, false, 1, 100000000, 800000000), bk)); CHECK_NOT_COMPLETE(rcv.addFrame(gen(0, "qwertyui", 1, false, 1, 100000001, 300000000), bk)); CHECK_COMPLETE( rcv.addFrame(gen(0, "abcd", 2, true, 1, 100000002, 900000000), bk)); ASSERT_TRUE(matchBufferContent(bufmgr.access(gen.bufmgr_key), "345678qwertyuiabcd")); ASSERT_EQ(100000000, rcv.getLastTransferTimestampMonotonic().toUSec()); ASSERT_EQ(800000000, rcv.getLastTransferTimestampUtc().toUSec()); } TEST(TransferReceiver, HeaderParsing) { Context<32> context; RxFrameGenerator gen(789); uavcan::TransferReceiver& rcv = context.receiver; uavcan::ITransferBufferManager& bufmgr = context.bufmgr; static const uavcan::TransferType ADDRESSED_TRANSFER_TYPES[3] = { uavcan::TransferTypeMessageUnicast, uavcan::TransferTypeServiceRequest, uavcan::TransferTypeServiceResponse }; uavcan::TransferID tid; /* * MFT, message broadcasting */ { gen.bufmgr_key = uavcan::TransferBufferManagerKey(gen.bufmgr_key.getNodeID(), uavcan::TransferTypeMessageBroadcast); uavcan::TransferBufferAccessor bk1(context.bufmgr, gen.bufmgr_key); CHECK_NOT_COMPLETE(rcv.addFrame(gen(0, "12345678", 0, false, tid.get(), 1), bk1)); CHECK_COMPLETE( rcv.addFrame(gen(0, "abcd", 1, true, tid.get(), 2), bk1)); ASSERT_TRUE(matchBufferContent(bufmgr.access(gen.bufmgr_key), "345678abcd")); ASSERT_EQ(0x3231, rcv.getLastTransferCrc()); tid.increment(); bk1.remove(); } /* * MFT, message unicast, service request/response */ for (unsigned i = 0; i < (sizeof(ADDRESSED_TRANSFER_TYPES) / sizeof(ADDRESSED_TRANSFER_TYPES[0])); i++) { gen.bufmgr_key = uavcan::TransferBufferManagerKey(gen.bufmgr_key.getNodeID(), ADDRESSED_TRANSFER_TYPES[i]); uavcan::TransferBufferAccessor bk2(context.bufmgr, gen.bufmgr_key); const uint64_t ts_monotonic = i + 10; CHECK_NOT_COMPLETE(rcv.addFrame(gen(0, "1234567", 0, false, tid.get(), ts_monotonic), bk2)); CHECK_COMPLETE( rcv.addFrame(gen(0, "abcd", 1, true, tid.get(), ts_monotonic), bk2)); ASSERT_TRUE(matchBufferContent(bufmgr.access(gen.bufmgr_key), "34567abcd")); ASSERT_EQ(0x3231, rcv.getLastTransferCrc()); tid.increment(); bk2.remove(); } /* * SFT, message broadcasting */ static const std::string SFT_PAYLOAD_BROADCAST = "12345678"; static const std::string SFT_PAYLOAD_UNICAST = "1234567"; { gen.bufmgr_key = uavcan::TransferBufferManagerKey(gen.bufmgr_key.getNodeID(), uavcan::TransferTypeMessageBroadcast); uavcan::TransferBufferAccessor bk(context.bufmgr, gen.bufmgr_key); const uavcan::RxFrame frame = gen(0, SFT_PAYLOAD_BROADCAST, 0, true, tid.get(), 1000); CHECK_SINGLE_FRAME(rcv.addFrame(frame, bk)); ASSERT_EQ(0x0000, rcv.getLastTransferCrc()); // Default value - zero // All bytes are payload, zero overhead ASSERT_TRUE(std::equal(SFT_PAYLOAD_BROADCAST.begin(), SFT_PAYLOAD_BROADCAST.end(), frame.getPayloadPtr())); tid.increment(); } /* * SFT, message unicast, service request/response */ for (unsigned i = 0; i < int(sizeof(ADDRESSED_TRANSFER_TYPES) / sizeof(ADDRESSED_TRANSFER_TYPES[0])); i++) { gen.bufmgr_key = uavcan::TransferBufferManagerKey(gen.bufmgr_key.getNodeID(), ADDRESSED_TRANSFER_TYPES[i]); uavcan::TransferBufferAccessor bk(context.bufmgr, gen.bufmgr_key); const uavcan::RxFrame frame = gen(0, SFT_PAYLOAD_UNICAST, 0, true, tid.get(), i + 10000U); CHECK_SINGLE_FRAME(rcv.addFrame(frame, bk)); ASSERT_EQ(0x0000, rcv.getLastTransferCrc()); // Default value - zero // First byte must be ignored ASSERT_TRUE(std::equal(SFT_PAYLOAD_UNICAST.begin(), SFT_PAYLOAD_UNICAST.end(), frame.getPayloadPtr())); tid.increment(); } }